KR20120040098A - Method for separating finished parts and residual scrap grid during laser cutting of sheet metal panel - Google Patents

Abstract

PURPOSE: A method for separating remaining scrapped lattice from cut product parts is provided to reduce scratches by supporting cut products and preventing the damage of cut product parts. CONSTITUTION: A method for separating remaining scrapped lattice from cut product parts includes the following: a sheet metal panel(2) is cut into smaller panel parts(2a to 2d) after the laser cutting process of cut product parts(21). A separated cut is formed such that at least one of remaining scrapped lattices(22a to 22d) from the separated sheet metal panel is supported by at least one supporting element(11) at a lattice edge(27). At least one separated cut is partially expanded from the remaining scrapped lattice.

Description

METHOD FOR SEPARATING FINISHED PARTS AND RESIDUAL SCRAP GRID DURING LASER CUTTING OF SHEET METAL PANEL}

The present invention provides a method for separating cut product portions, which are still connected to the remaining scrap gratings by microjoints, resulting from placing a sheet metal panel on a workpiece pedestal formed of a plurality of support elements and laser cutting from the remaining scrap gratings of the sheet metal panel. It is about a method.

Such separation methods are well known. The sheet metal panel to be machined is placed on the workpiece pedestal by machine or manually and then lifted from the workpiece pedestal with the part of the cut product still connected by the microjoint after laser cutting. Separating the cut product portions from the remaining scrap grating is preferably done manually by knocking off the cut product portions. However, for the machine operator to be able to lift the sheet metal panel out of the workpiece pedestal, the sheet metal panel must not exceed a certain area and a certain weight. In known separation methods, the cut product parts can be scratched and scratched due to being placed on the support elements of the workpiece pedestal, which degrades the parts and, if the quality requirements are stringent, costly post-processing Let's need

On the other hand, the object of the present invention is to improve the separation method mentioned at the outset so that even sheet metal panels that cannot be manipulated manually can be processed and the cutting product parts are not as damaged as possible during processing.

Such an object is to cut the sheet metal panel into smaller sheet metal panel portions by at least one separation cut that at least partially extends from the remaining scrap grating after laser cutting of the cut product portions according to the invention in the separation method. The separation cut is solved by forming a separation cut such that at least one of the remaining scrap grid portions of the sheet metal panel portions separated from each other by the separation cut continues to be supported on the at least one support element at the grid edge on the separation cut side.

That is, according to the invention, the sheet metal panel is cut into smaller sheet metal panel parts which can be easily manipulated by the machine operator by one or more separate cuts after laser cutting of the cut product parts. At this time, the separation cut to be made between the sheet metal panel portions is subsequently continued by supporting elements provided in the area at the grid edges of the one, multiple, or all remaining scrap grid portions of the sheet metal panel portions. It is formed to be supported. In this way, optimal support of the individual sheet metal panel parts is ensured on the one hand, thereby reliably preventing damage to the cut product parts due to the sheet metal panel parts tilting away from the workpiece support, and on the other hand as far as possible With fewer support elements supporting the cut product portions, ideally no support element supports the cut product portion, thereby avoiding the formation of scratches and at the same time resulting in a significant improvement in the quality of the cut product portions. do.

At least one separation cut preferably extends throughout the remaining scrap grating. However, it is also possible for the separate cut to be formed in part by the cut of the part of the cut product.

Arranging the backing elements and distributing and placing the part of the cut product to be cut into the sheet metal panel is highly desirable to be adjusted to one another such that the overlying sheet metal panel is supported by the backing elements only in the region of the remaining scrap grid. This eliminates scrapes by the workpiece pedestal at all cut product parts.

The separation cuts are preferably made in the separation lanes that are already left empty when distributing and placing the cut product portions to be cut in the sheet metal panel to be spaced apart from the cut product portions in the remaining scrap grid. The separating lanes can be made with sufficient separation from the supporting elements and the cut product portions so that the cut product portions as well as the remaining scrap grating portions are attached to the supporting elements by the laser beam making the separating cut. It is preferred to be of a width such that it is not damaged in any other way.

If the supporting elements are provided in two rows along the separation cut, for example along two two stacking bridges, the separation cut can be made between the two rows (in particular in a straight line in some cases) and thus in the separation cut. The sheet metal panel portions separated from each other are then laid on a row of support elements. However, to reduce stuttering, it may be preferable to provide only one row of support elements along the separation cut. In that case, the separation cut preferably extends in a jagged shape, in particular in a zigzag, sawtooth shape, or wave shape so that the sheet metal panel portions continue to lie on the backing elements.

The workpiece can be arranged as intended, with only a few of the plurality of support elements movable in the height direction to arrange the support elements as desired, for example by raising the support elements that are vertically movable or by folding the support elements that can be folded. It is preferable to arrange in the plane of the pedestal. Alternatively, the supporting elements may be provided on the working table of the laser machine as intended.

Where possible mutual gaps (lattice mesh) of the collapsible support elements in the workpiece pedestal are fixedly provided, the distribution of the part of the cut product to be cut into the sheet metal panel is selected depending on the support elements.

It is desirable to lift the sheet metal panel parts manually from the workpiece pedestal. For that purpose, the individual sheet metal panel portions must not exceed a certain area and a certain weight, and also their longitudinal size must not exceed a certain value.

The invention also relates to a computer program product having code means configured to perform all the steps of the above-described method when the program is executed in a data processing system.

Further advantages and preferred configurations of the subject matter of the present invention will become apparent from the following detailed description, the accompanying drawings, and the claims. In addition, the features described above or now below may be used individually or individually in multiples of any combination, in accordance with the present invention. The embodiments shown and described are not to be understood as a final enumeration, but rather have an exemplary nature for the description of the invention.

In the present invention, after laser cutting of the cut product portions, the sheet metal panel is cut into smaller sheet metal panel portions that can be easily manipulated by a machine operator by one or more separate cuts, with one, multiple, or The separation cut is formed such that all remaining scrap grating portions continue to be supported by the supporting elements provided in that area at the grid edges on the separation cut side. In this way, optimal support of the individual sheet metal panel parts is ensured on the one hand, thereby preventing damage to the cut product parts due to the sheet metal panel parts being tilted off the workpiece support, and on the other hand as little support as possible. The fact that the elements support the cut product portions or the backing elements do not support the cut product portions at the same time avoids the formation of scratches and at the same time reduces the amount of scrap, thereby significantly improving the quality of the cut product portions.

1 shows a known laser processor for laser cutting of sheet metal panels.
2a to 2c show the temporal sequence of the method according to the invention at the time of laser cutting of a sheet metal panel, in which FIG. 2a distributes to the sheet metal panel the sheet metal panel placed on the workpiece pedestal of the laser machine and the part of the cut product to be cut. 2b shows a sheet metal panel placed on a workpiece pedestal and cut cut product portions, and FIG. 2c shows a sheet metal panel placed on a workpiece pedestal, cut into four sheet metal panel sections. Shown.
3 and 4 show two other embodiments of cutting a sheet metal panel on four workpiece pedestals into four sheet metal panel sections.
5 is a flow chart of a method according to the invention.

1 shows a laser machine 1 known as a "TruLaser" for laser cutting a plate-like workpiece 2, referred to as a sheet metal panel. Such a laser processing machine 1 comprises a cutting device 3 with a laser equipment 4, a work table 7 with an external beam guide 5 and a processing head 6, and a workpiece support 8. do. During laser cutting, cutting noise, slag particles, and small waste portions are sucked through the suction device 9 mounted on the work table 7. The machining head 6 is mounted to the cross beam 10 and is formed to be movable in a plane parallel to the workpiece support 8. In the embodiment shown, the machining head 6 is formed so as not to be able to move up and down in a direction perpendicular to the sheet metal panel 2, and the change of the focus position is caused by the optical elements in the machining head 6, for example adaptive control optics. It is set via an adaptive optic. Alternatively, the machining head 6 may be formed to be movable up and down in a direction perpendicular to the workpiece pedestal 8 for changing the focal position.

The workpiece pedestal 8 is preferably formed by a plurality of support elements 11 having support point peaks formed in a triangle, the support elements 11 defining a support plane for the sheet metal panel 2 to be machined. do. The supporting elements 11 are arranged in a predetermined grid and can be folded down or moved down individually or along the strip so as not to support the sheet metal panel 2.

FIG. 2A shows a sheet metal panel 2 placed on a workpiece pedestal of the laser machine 1 shown in FIG. 1, from which a plurality of cut product portions 21 are cut from the sheet metal panel 2. It is separated from the remaining scrap grating 22 of (2). The sheet metal panel 2 rests on the supporting elements 11 of the workpiece pedestal 8, which are indicated by crosses. At this time, arranging the supporting elements 11 and distributing and placing the cut product portions 21 to be cut in the sheet metal panel is such that the sheet metal panel 2 is provided solely in the region of the remaining scrap grid 22. 11) are adapted to each other to be supported on. The possible mutual spacings of the arranging backing elements 11, ie, when the grating network is fixedly given in advance, distributing and disposing the cut product portions 21 to be cut into the sheet metal panel 2 is a sheet metal panel 2. It is desirable to be adapted to the lattice net of the backing elements 11 such that it is supported entirely on the backing elements 11 only in the region of the remaining scrap lattice 22.

In the embodiment shown, 24 evenly cut product parts 21 arranged in four columns and six rows are cut. The interline spacing between the third and fourth rows is enlarged due to the horizontal separation lane 23a additionally sandwiched therein, and the spacing between the second and third columns additionally interleaved therein. Due to the vertical separation lane 23b, the lateral edges of the separation lanes 23a and 23b are shown by dashed lines 24.

FIG. 2B shows the sheet metal panel 2 after cutting of the cut product portions 21, the cut product portions 21 still being retained by the so-called microjoint (connection bridge) 25. Caught on

Then, as shown in FIG. 2C, the sheet metal panel 2 is cut into four small sheet metal panel portions 2a to 2d by two separate cuts 26a and 26b extending from the remaining scrap grating 22. The small sheet metal panel portions 2a to 2d can be operated more simply or only by the machine operator based on their small weight and their small dimensions. In order to ensure reliable support of the sheet metal panel portions 2a to 2d after separation, the supporting elements 11 which fully support the four sheet metal panel portions 2a to 2d are provided with the area of the separating cuts 26a and 26b. Should be provided in Thus, each of the separation cuts 26a, 26b is formed on the separation cut side even after the remaining scrap lattice portions 22a to 22d of the sheet metal panel portions 2a to 2d separated by the separation cuts 26a and 26b are separated. It is formed to continue to be supported on at least one support element 11 at the grating edges 27. In order to minimize the edge, generally only one row of support elements 11 are arranged along the separation cuts 26a, 26b. In that case, the separation cuts 26a, 26b extend zigzag (or in the form of sawtooth or wave) between the bearing elements 11, whereby the bearing elements 11 are connected with one sheet metal panel portion. Alternately supports other sheet metal panels. Then, the sheet metal panel portions 2a to 2d are manually lifted out of the workpiece pedestal 8 individually, and then each of the cut product portions 21 that are not in contact with the supporting elements 11 during the entire machining. Manually peel off the remaining scrap grating portions 22a to 22d. The method described above allows for maximum cut product part quality with good handling and minimal blemishes.

As shown in FIG. 2A, when distributing and placing the cut product portions 21 to be cut into the sheet metal panel 2, a first auxiliary line 28a extending here horizontally and a second beam extending vertically here. Shipbuilding 28b divides sheet metal panel 2 into four sheet metal panel sections. Such auxiliary lines 28a, 28b are such that the area, weight, and length and width dimensions of the four sheet metal panel sections are operable to the machine operator. The sheet metal panel sections are thus arranged to be lifted separately from the workpiece pedestal 8 to separate the cut product portions 21. The cut product portions 21 are arranged on the four sheet metal panel sections so that the separation lanes 23a, 23b are in the area of the auxiliary lines 28a, 28b. The separating lanes 23a and 23b become areas of the sheet metal panel 2 in which the separating cuts 26a and 26b are already disposed at the time of placement.

FIG. 3 shows a sheet metal panel 2 divided into four sheet metal panel portions 2a to 2d by a separate cut 26c according to the invention similar to FIG. 2c and a conventional separate cut 26c. In the sheet metal panel 2 the support elements 11 are arranged along three rows, for example along three support strips. In this case too, the separating cut 26b extends so that the sheet metal panel portions 2a to 2d rest on at least one supporting element 11 along the grid edges 27 on the separating cut side according to the invention. do. In that regard, the center of gravity of each sheet metal panel portion 2a to 2d is in the polygonal plane formed by the supporting elements 11 belonging to the respective sheet metal panel portion 2a to 2d, whereby the sheet metal panel The parts 2a to 2d are considered so that they do not fall off and lie stably.

FIG. 4 shows a sheet metal panel 2 divided into four sheet metal panel portions 2a to 2d by two separate cuts 26a and 26b according to the invention similar to FIG. 2c. In such sheet metal panel 2, unlike in FIG. 2, the sheet metal panel portion 2d in the region of the separation cut 26a is supported only by the toothed edges 27 of the remaining scrap grid portion 22d. 11) but also on the support element 11 by its cut cut product portion 21a which is connected by a microjoint. In addition, the separation cut 26b does not extend all over in the original remaining scrap grating 22 but is formed in part by the cut of the cut product portion 21a.

5 shows a method according to the invention in the form of a flowchart. In step S1, the cut product portions 21 to be cut are placed or placed on the sheet metal panel 2 according to a known layout strategy such as by a rectangular layout or a free geometric shape layout. In step S2, the sheet metal panel 2 is divided into four sheet metal panel sections by two auxiliary lines 28a and 28b. In this case, the division may be automatically performed by the programming system or the division may be performed manually by a programmer. Depending on dispensing and placing the cut product portions on the sheet metal panel, separation lanes 23a and 23b can be created in the area of the auxiliary lines 28a and 28b to which the separation cuts 26a and 26b can extend. It may be necessary to move the cut product portions 21 on the sheet metal panel 2. In step S3, it is checked whether sufficient space for the separation lanes 23a and 23b exists in the region of the auxiliary lines 28a and 28b. If the space in the area of the auxiliary lines 28a, 28b is not sufficient to arrange the separation lanes having the required width (N in step S3), the separation lanes 23a, 23b having the required width in step S4 are visible. The cut product portions 21 are moved on the sheet metal panel 2 to occur in the region of the ships 28a and 28b. After step S4 or if there is sufficient space in the separation lanes in the region of the auxiliary lines 28a, 28b (J in step S3), the work table (where the auxiliary lines 28a, 28b extend in step S5) 7) Arrange the supporting elements 11 on. After laser cutting (step S6) of the cut product portions 21, the sheet metal panel 2 is cut into small sheet metal panel portions 2a to 2d in the separation lanes 23a and 23b between the four sheet metal panel portions. Separation cuts 26a and 26b to be divided are generated (step S7). At this time, each of the separation cuts 23a and 23b has separation lanes so that the separation cuts 23a and 23b maintain a minimum distance with respect to each of the supporting elements 11 to prevent damage of the supporting elements by the laser beam. It is located at 23a, 23b.

2: sheet metal panel 2a to 2d: sheet metal panel portion
8: workpiece support 11: support element
21: Cutting product part 22: Remaining scrap grating
22a to 22d: remaining scrap grating portion
23a. 23b: separation lane 25: microjoint
26a, 26b: Separate cut 27: Grid edge

Claims (10)

Cutting still connected to the remaining scrap grating 22 by the micro joint 25, which occurs when laser cutting and sheet metal panel 2 on the workpiece pedestal 8 formed of a plurality of supporting elements 11. In the method of separating the product portions 21 from the remaining scrap grid 22 of the sheet metal panel 2,
After laser cutting of the cut product portions 21, the sheet metal panel 2 is reduced to smaller sheet metal panel portions 2a to 26 by at least one separate cut 26a, 26b extending at least partially from the remaining scrap grating 22. 2d), wherein at least one of the remaining scrap grating portions 22a to 22d of the sheet metal panel portions 2a to 2d separated from each other by the separating cuts 26a and 26b has a grating edge ( A separation cut (26a, 26b) so as to continue to be supported on at least one support element (11). 2. The remaining scrap grating portions 22a to 22d of the sheet metal panel portions 2a to 2d separated from each other by the separating cuts 26a and 26b have the grating edges 27 on the side of the separating cut. Forming separate cuts (26a, 26b) so as to continue to be supported on at least one support element (11). Method according to one of the preceding claims, characterized in that the at least one separating cut (26a, 26b) extends through the entirety of the remaining scrap grating (22). The sheet metal panel (2) according to any of the preceding claims, wherein the sheet metal panel (2) overlies the arrangement of the supporting elements (11) and the dispensing arrangement of the cut product portions (21) to be cut into the sheet metal panel (2). Adjusting to one another such that they are supported by the supporting elements (11) only in the region of the grating (22). Method according to one of the preceding claims, characterized in that a separation cut (26a, 26b) is made in the remaining separation lanes (23a, 23b) emptied in the remaining scrap grating (22) between the cut product portions (21). Method according to one of the preceding claims, characterized in that the separating cuts (26a, 26b) extend in a zigzag form, saw tooth form or wave form. The method according to any one of the preceding claims, characterized in that only a few of the plurality of support elements movable in the height direction are arranged in the plane of the workpiece support as intended, in order to arrange the support elements 11 as desired. How to. The method according to any one of the preceding claims, wherein the dispensing arrangement of the part of the cut product 21 to be cut into the sheet metal panel 2 is selected or dependent upon the support elements 11 forming the workpiece pedestal 8. The reverse method. Method according to one of the preceding claims, characterized in that the sheet metal panel portions (2a to 2d) are lifted manually from the workpiece pedestal (8). A computer program product comprising code means configured to perform all steps of the method according to any one of claims 1 to 8 when a program is executed in a data processing system.

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